JP2007025001A - Sound recording device, method, and program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a sound recording device which can continue recording without being restricted by the file size. <P>SOLUTION: When sequentially recording the data D3 encoded in an AD/DA converter circuit 24 and a DSP20B in a WAV format sound file on a flash memory 21, this device creates another audio file AF2 with the CPU 20A in the controller 20 before the size of the recording audio file AF1 reaches its upper limit 2 [GB] and switches to the audio file AF2 to record the encoded data D3. Thus, it can continue the sound recording until it consumed the whole capacity of the flash memory 21 without restricted by the upper limit 2 [GB] specified in the WAV format. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an audio recording device, an audio recording method, and an audio recording program, and is suitable for application to, for example, an IC (Integrated Circuit) recorder that encodes audio and records it in a semiconductor memory.

  In recent years, IC recorders have been designed to collect ambient sounds with a microphone and record them in a semiconductor memory as encoded data, and are particularly compact and lightweight so that they can be easily carried, such as conferences and lectures. The one that can record voices at various places is becoming popular.

  In such an IC recorder, since the storage capacity of the semiconductor memory is limited to 128 [MB], for example, it is assumed that the content of a person's conversation is mainly listened to, and a sampling rate of 8 kHz, 4-bit quantization is performed. In addition, there is one that can record voice for as long a time as possible while maintaining sound quality capable of listening to a conversation by recording encoded data at a low bit rate such as 32 [kbps] in monaural.

Some IC recorders can be connected to a personal computer via a USB (Universal Serial Bus) cable or the like. In this case, the user can operate the personal computer to record in the IC recorder. There has also been proposed one that can perform an editing process or the like of the audio data (for example, see Patent Document 1).
JP 2004-264912 A (pages 8-9, FIG. 3)

  By the way, in the IC recorder having such a configuration, it is assumed that sound such as musical instrument performance or human singing voice is recorded with high sound quality. For example, the sampling rate is 96 [kHz], 24-bit quantization and stereo (2 channels), That is, it may be possible to record at a high bit rate of 4.6 [Mbps] and increase the capacity of the semiconductor memory to 4 [GB] or the like.

  In this case, when the IC recorder is connected to the personal computer, the semiconductor memory of the IC recorder is similar to the hard disk drive of the personal computer so that the encoded data recorded from the personal computer to the IC recorder can be handled as a file. A method of formatting in the FAT32 (File Allocation Table 32) format and storing the encoded data as a WAV format file is also conceivable.

  However, due to the limitations of the WAV format, the upper limit size of one file is 2 [GB]. Therefore, if the IC recorder starts recording from a state where nothing is recorded in the semiconductor memory (that is, empty), the remaining 2 [GB] is free when the file size reaches 2 [GB]. In spite of this, there is a problem that the recording is ended by closing the file, that is, the long-time sound corresponding to the capacity of the semiconductor memory cannot be recorded due to the limitation of the file size.

  The present invention has been made in view of the above points, and intends to propose an audio recording apparatus, an audio recording method, and an audio recording program capable of continuing recording without being limited to the file size.

  In order to solve such a problem, in the present invention, when encoded data obtained by encoding sound is sequentially recorded in a sound file of a predetermined format, a new sound file is recorded before the size of the sound file being recorded reaches the upper limit size of the sound file. An audio file is created, and the recording destination of the encoded data is switched to the new audio file.

  As a result, since the audio file that is the recording destination of the encoded data can be switched during the audio recording, the audio recording can be continued without being affected by the upper limit size in the audio file.

  According to the present invention, since the audio file that is the recording destination of the encoded data can be switched during the audio recording, the audio recording can be continued without being affected by the upper limit size of the audio file. Thus, an audio recording device, an audio recording method, and an audio recording program that can continue recording without being limited by the file size can be realized.

  Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings.

(1) Configuration of IC Recorder (1-1) External Configuration As shown in FIG. 1, an IC (Integrated Circuit) recorder 1 is carried to various places by a user, and surrounding sounds (that is, people's voices) at each place. This is based on the premise of recording voice, instrument sounds, etc.).

  The IC recorder 1 includes an LCD (Liquid Crystal Display) 3 on the surface of the housing 2, a VU (Volume Unit) meter 4 for the left channel above the LCD 3, a VU meter 5 for the right channel, and various types below the LCD 3. An operation button group 6 is provided.

  The operation button group 6 includes a play button 6A, a stop button 6B, a record button 6C, a pause button 6D, a fast forward button 6E, a fast reverse button 6F, a menu button 6G, a file division button 6H, and an illumination button 6I. Wait for a press operation.

  Further, the IC recorder 1 is provided with a right channel microphone 7 and a left channel microphone 8 at the top of the housing 2, and an arc-shaped metal made to protect the right channel microphone 7 and the left channel microphone 8. The covers 9 and 10 are provided so as to cover them.

  Further, a volume adjustment knob 11 is provided on the left side surface of the housing 2, and a recording level adjustment knob 12 is provided on the right side surface.

  In practice, the IC recorder 1 encodes audio into high bit rate data such as a sampling rate of 96 [kHz], a quantization bit rate of 24 bits, and stereo (2 channels), that is, 4.6 [Mbps]. By storing as a compressed WAV format file, it is possible to record high quality sound such as musical instrument performance or human singing voice (details will be described later).

(1-2) Circuit Configuration As shown in FIG. 2, the IC recorder 1 is configured to perform overall control by the control unit 20. The control unit 20 is configured around a CPU (Central Processing Unit) 20A, and a RAM (Random Access Memory) (not shown) that stores various programs such as a basic program and a voice recording program read from a ROM (Read Only Memory) (not shown). By expanding and executing the functions, various functions such as voice recording processing and playback processing are realized.

  When the CPU 20A of the control unit 20 recognizes that each button 6A to 6I (FIG. 1) of the operation button group 6 has been operated by the user, the CPU 20A executes processing corresponding to the operation.

  When the CPU 20A of the control unit 20 recognizes that, for example, the recording button 6C (FIG. 1) of the operation button group 6 has been pressed, it flashes a WAV format audio file AF having a file name corresponding to the date, time, etc. It is created in the memory 21 and the voice file AF is opened so that voice data can be written.

  Incidentally, the flash memory 21 has a storage capacity of 4 [GB], is formatted in the FAT 32 (File Allocation Table 32) format, and is provided with ten folders. The CPU 20A of the control unit 20 includes the operation button group 6 The audio file AF is created in any one folder selected by the operation via the.

  Subsequently, the CPU 20A of the control unit 20 starts the supply of power to the right channel microphone 7 and the left channel microphone 8 from a power control unit (not shown), so that surrounding sounds (that is, human voices, musical instrument sounds, etc.) ) Are respectively converted into electric signals, which are amplified to input audio signals S1 and S2 of predetermined levels by microphone amplifiers 22 and 23, respectively, and the input audio signals S1 and S2 are converted into AD / DA (Analog to Digital). / Digital to Analog) is continuously supplied to the conversion circuit 24.

  The AD / DA conversion circuit 24 sequentially generates input sound data D1 and D2 by performing analog-digital conversion on the input sound signals S1 and S2, respectively, and sequentially supplies them to a DSP (Digital Signal Processor) 20B of the control unit 20. It is made like that.

  The DSP 20B of the control unit 20 divides the input audio data D1 and D2 into unit times of, for example, 0.5 [seconds], performs linear encoding processing for each time unit, and combines data for two channels into one. As a result, linear PCM (Pulse Code Modulation) encoded data D3 is sequentially generated, and these are sequentially supplied to the flash memory 21.

  At this time, the CPU 20A of the control unit 20 writes the encoded data D3 sequentially into the audio file AF of the flash memory 21, thereby continuing the recording process while sequentially increasing the file size of the audio file AF.

  Further, the AD / DA conversion circuit 24 generates analog audio signals S3 and S4 by performing digital / analog conversion on the input audio data D1 and D2 immediately after the analog / digital conversion, and amplifies them by the headphone amplifiers 25 and 26. Then, by sending it to an external headphone 40 connected to the headphone terminal 14, the user can audition (monitor) the sound currently being recorded via the headphone 40.

  Further, for example, as shown in FIG. 3, the CPU 20A of the control unit 20 includes a peak level meter display unit 71 that displays the volume level of the left channel and the volume level of the right channel, a REC mark 72 that indicates that recording is in progress, and a playback time. , A time display unit 73 indicating the elapsed recording time, the remaining recordable time, etc., an icon display unit 74 indicating the presence / absence of a Memory Stick (registered trademark) and the remaining battery level, a folder number (in this case “03”), and the number of files (in this case “29/29”) and file display section 75 indicating the file name (in this case “05012403.wav”), sampling rate (in this case “96.00 kHz”), number of quantization bits (in this case “24 bits”), etc. Detailed information display section 76, memory icon 77 representing the usage ratio of the entire IC recorder 1 with respect to flash memory 21 by the length of the bar. By displaying the display screen 70 of memory remaining capacity display unit 78 shown more LCD 3, it is made so as to visually recognize the recording state such as recording level and elapsed recording time to the user.

  Incidentally, the CPU 20A of the control unit 20 closes the sound file AF when the stop button 6B (FIG. 1) of the operation button group 6 is operated, and ends a series of recording processes.

  As described above, when the recording button 6C of the operation button group 6 is operated, the IC recorder 1 converts the surrounding sound into an electrical signal, and sequentially generates processes such as amplification, analog-digital conversion, and encoding. The encoded data D3 is sequentially recorded in the audio file AF of the flash memory 21.

  By the way, the IC recorder 1 is connected to a personal computer (not shown) via the USB interface 27, so that the audio file AF can be transferred to / from the personal computer.

  In practice, when the CPU 20A of the control unit 2 recognizes that the USB interface 27 is connected to a personal computer via a USB cable (not shown), the “single operation mode” in which the IC recorder 1 alone can perform the above-described recording processing and the like. By changing the operation mode from “storage mode” to “storage mode”, the flash memory 21 can be used as an external storage of the personal computer, that is, recognized as one drive from the OS (Operating System) of the personal computer.

  At this time, the personal computer can recognize the audio file AF recorded in the flash memory 21 as a normal WAV format file, and copy or move the audio file AF in units of files based on a user operation. Alternatively, editing processing can be performed using a dedicated voice editing program or the like.

  When the CPU 20A of the control unit 2 recognizes that the USB cable (not shown) has been removed from the USB interface 27, the CPU 20A returns the operation mode from the “storage mode” to the “single operation mode”, thereby the IC recorder 1 alone. Thus, various processes such as the recording process described above can be performed.

  As described above, when the IC recorder 1 is connected to the personal computer via the USB interface 27, the flash memory 21 is recognized as the external storage of the personal computer, and the audio file AF is handled as a normal WAV format file. Has been made.

(2) Recording process Since the IC recorder 1 has the flash memory 21 with a storage capacity of 4 [GB] as described above, for example, the user makes full use of the storage capacity of the flash memory 21 for a long time. There is a possibility of continuous recording of time.

  However, in the WAV format, which is the file format of the audio file AF, the upper limit size of one file is defined as 2 [GB], and the IC recorder 1 stores encoded data D3 exceeding 2 [GB] in one audio file AF. Can not write to.

  Incidentally, if the IC recorder 1 sets the audio file AF to a size of 2 [GB] or more, the audio file AF is converted into a normal WAV format file from the personal computer connected to the IC recorder 1 due to a compatibility problem. Will not be able to handle.

  Therefore, when the IC recorder 1 continues the recording process for a long time and writes the encoded data D3 exceeding 2 [GB] in the flash memory 21, the size of the audio file AF (hereinafter referred to as the audio file AF1) is 2. A new audio file AF (hereinafter referred to as audio file AF2) is created immediately before exceeding [GB], and the writing destination of the encoded data D3 is switched from the audio file AF1 to the audio file AF2. The encoded data D3 is written by dividing the audio file AF.

  Incidentally, the control unit 20 considers the time required for the process of creating the audio file AF2, and creates the audio file AF2 when the size of the audio file AF1 becomes 1.96 [GB], which is slightly before the size of 2 [GB]. Is started and the writing destination of the encoded data D3 is switched to the audio file AF2 immediately before the size of the audio file AF1 becomes 2 [GB], so that the use efficiency of the audio file AF is improved and the recording process is not interrupted. Has been made.

  Further, when the IC recorder 1 switches the writing destination of the encoded data D3 from the audio file AF1 to the audio file AF2, the display screen 70 (FIG. 3) although the actual audio file AF1 and the audio file AF2 have different file names. By not changing the file name displayed on the file display unit 75), the user is prevented from being aware that the sound is divided into two sound files AF and recorded.

  Here, a recording processing procedure when the IC recorder 1 actually records surrounding sounds will be described with reference to the flowchart of FIG.

  When the control unit 20 of the IC recorder 1 recognizes that the recording button 6C (FIG. 1) of the operation button group 6 has been pressed, it starts the recording processing procedure RT1 and proceeds to step SP1. In step SP1, the control unit 20 creates an audio file AF1 in the currently selected folder of the flash memory 21 and opens the audio file AF1 so that the encoded data D3 can be written therein, and then proceeds to the next step SP2. .

  In step SP2, the control unit 20 determines whether or not the current file size of the audio file AF1 has reached 1.96 [GB], which is immediately before 2 [GB]. If a negative result is obtained here, this means that the encoded data D3 can still be added and written to the audio file AF1, and at this time, the control unit 20 proceeds to the next step SP4.

  On the other hand, if a positive result is obtained in step SP2, this indicates that the encoded data D3 cannot be written any more into the audio file AF1, and at this time the control unit 20 proceeds to the next step SP3.

  In step SP3, the control unit 20 closes the voice file AF1 in the flash memory 21, creates and opens a new voice file AF2 in the same folder as the voice file AF1, and sets the writing destination of the encoded data D3 as the voice file. The sound file AF2 is changed from AF1 to the next step SP4 without changing the file name displayed on the file display section 75 of the display screen 70 (FIG. 3).

  In step SP4, the control unit 20 determines whether or not the flash memory 21 has an empty capacity. If a positive result is obtained here, this means that the encoded data D3 can still be written to the flash memory 21, that is, the recording process can be continued. At this time, the control unit 20 performs the next step SP5. Move on.

  In step SP5, the control unit 20 writes the encoded data D3 for a unit time (that is, for 0.5 [second]) to the voice file AF that is open at this time (that is, the voice file AF1 or the voice file AF2). The process proceeds to step SP6.

  In step SP6, the control unit 20 determines whether or not the stop button 6B (FIG. 1) of the operation button group 6 has been pressed. If a negative result is obtained here, this means that the user still has the intention to continue the recording process. At this time, the control unit 20 returns to step SP2 again, and the encoded data D3 is converted into an audio file. A series of processes for writing to AF is repeated.

  On the other hand, if a negative result is obtained in step SP4, this means that the encoded data D3 for a total of 4 [GB] has already been written in the flash memory 21, and no new encoded data D3 can be added any more. At this time, the control unit 20 moves to the next step SP7.

  If a positive result is obtained in step SP6, this indicates that the user has indicated an intention to stop recording, and at this time, the control unit 20 proceeds to the next step SP7.

  In step SP7, the control unit 20 closes the currently opened audio file AF, stops the power supply to the right channel microphone 7 and the left channel microphone 8 (FIG. 2) by the power control unit (not shown). After stopping a series of processes in the microphone amplifiers 22 and 23, the AD / DA conversion circuit 24, the DSP 20B of the control unit 20, and the like, the process proceeds to the next step SP8 and the recording processing procedure RT1 is completed.

(3) Display of audio file in personal computer By the way, as described above, when the encoded data D3 becomes 2 [GB] or more by continuing the recording process, the IC recorder 1 first displays the encoded data D3. Although the file is written to the audio file AF1 and switched to the audio file AF2 in the middle, the file name (in this case, “05012403.wav”) displayed on the file display unit 75 of the display screen 70 (FIG. 3) before and after the change is intentionally changed. It is made not to do.

  That is, the IC recorder 1 processes the file name of the audio file AF in the flash memory 21 and presents it to the user.

  On the other hand, when the IC recorder 1 is connected to a personal computer (not shown) via a USB cable (not shown) as described above, the operation mode is changed to “storage mode”, whereby the flash memory 21 is connected to the personal computer (not shown). Make it recognized as an external storage drive of the computer.

  At this time, the IC recorder 1 notifies the personal computer as it is without processing the file name or the like of the audio file AF in the flash memory 21, so that it is actually stored in the flash memory 21, for example, as shown in FIG. Audio file AF1 (in this case, “05012403-01.wav”) and audio file AF2 (in this case, “05012403-02.wav”) are recognized as original independent files by the personal computer. The information is displayed in a window W on a display screen in the personal computer.

(4) Operation and Effect In the above configuration, the IC recorder 1 creates a WAV format audio file AF1 in the flash memory 21 when the recording button 6C (FIG. 1) of the operation button group 6 is pressed, The encoded data D3 obtained by encoding the voice is sequentially written in the voice file AF1.

  At this time, the IC recorder 1 creates the audio file AF2 immediately before the size of the audio file AF1 exceeds 2 [GB], switches the writing destination of the encoded data D3 to the audio file AF2, and continues the recording process.

  Therefore, since the IC recorder 1 can switch and write the encoded data D3 to the audio file AF1 and the audio file AF2 each having a size of 2 [GB] or less, it can be set to 2 [GB] which is the upper limit size defined in the WAV format. Without being limited, the recording process can be continued until the free space of the flash memory 21 is used up.

  At this time, the IC recorder 1 can maintain the compatibility of the file format by suppressing the file size within 2 [GB]. Therefore, the audio file AF1 and the audio file AF2 are set as normal WAV format files in an external personal computer or the like. It can also be handled, and the audio editing process can also be performed by the user with a general audio editing program, etc., so the convenience is greatly improved compared to the case where a dedicated file format is adopted while ignoring compatibility. Can be improved.

  Further, since the IC recorder 1 does not dare to change the file name displayed on the file display unit 75 of the display screen 70 (FIG. 3), it extends over the two audio files AF1 and AF2 due to the restriction of 2 [GB] in the WAV format. Thus, the user can be made to recognize as if one audio file AF has been generated in one recording process without making the user aware of the recording.

  Furthermore, when the IC recorder 1 is connected to an external personal computer or the like, the voice file AF is managed or edited by notifying the file name of the voice file AF recorded in the flash memory 21 as it is. For the user who wants to perform the recording, it can be recognized that the file is divided into two files of the audio file AF1 and the audio file AF2, and the file name is recognized correctly.

  According to the above configuration, when the IC recorder 1 sequentially writes the encoded data D3 obtained by encoding the sound into the sound file AF1, the sound file AF2 immediately before the size of the sound file AF1 exceeds 2 [GB]. , And the recording destination is continued by switching the writing destination of the encoded data D3 to the audio file AF2 without being limited to 2 [GB] which is the upper limit size defined in the WAV format. Recording processing can be continued until the free space in the memory 21 is used up, and thus recording can be continued without being limited by the file size.

(5) Other Embodiments In the above-described embodiment, when the writing destination of the encoded data D3 is switched from the audio file AF1 to the audio file AF2, the file display section of the display screen 70 (FIG. 3). Although the case where the file name displayed in 75 is not changed has been described, the present invention is not limited to this, and the file name of the file display unit 75 is changed darely, and the writing destination of the encoded data D3 is set as a voice. The user may be actively notified that the file AF1 has been switched to the audio file AF2.

  In the above-described embodiment, when the IC recorder 1 is connected to a personal computer (not shown), as shown in FIG. 5, the audio file AF1 actually recorded in the flash memory 21 and The case where the audio file AF2 is displayed on the display screen as an independent file with the original file name has been described. However, the present invention is not limited to this, and the file operation dedicated to the IC recorder 1 is performed on a personal computer, for example. The program may be executed so that the audio file AF1 and the audio file AF2 are handled as one audio file on the file operation program.

  In this case, the IC recorder 1 may be connected to various external devices such as a dedicated sound editing device via a USB cable in addition to the personal computer.

  Further, in the above-described embodiment, since the storage capacity of the flash memory 21 is 4 [GB] and the upper limit size of the WAV format is 2 [GB], the encoded data D3 is divided into two audio files AF. However, the present invention is not limited to this. For example, when the storage capacity of the flash memory 21 is 8 [GB] or 16 [GB], the encoded data D3 is 2 [GB]. ] May be divided and written into four or eight audio files AF.

  Furthermore, in the above-described embodiment, the case where the audio file AF is created in the WAV format and the encoded data D3 is written has been described. The encoded data D3 may be written in the audio file AF in the file format, and further compression processing may be performed.

  Furthermore, although the case where the upper limit size of the audio file AF is defined as 2 [GB] has been described in the above-described embodiment, the present invention is not limited to this, and for example, 1 [GB], 4 [GB], etc. The present invention may be applied when the upper limit size of the audio file AF is variously defined.

  Furthermore, in the above-described embodiment, the case where the audio file AF is divided every 2 [GB] which is the upper limit size of the file format (that is, WAV format) has been described, but the present invention is not limited to this. For example, the audio file AF may be divided according to the upper limit size determined by various restriction conditions, such as dividing the audio file AF every 1 [GB] due to hardware restrictions in the IC recorder 1.

  Further, in the above-described embodiment, the case where the present invention is applied to the IC recorder 1 that creates the audio file AF in the flash memory 21 and writes the encoded data D3 has been described. However, the present invention is not limited to this. Instead, for example, the present invention may be applied to various audio recording apparatuses that encode audio and record it in an audio file, such as a hard disk recorder that creates audio file AF in a hard disk drive and writes encoded data D3.

  Further, in the above-described embodiment, the case has been described in which the IC recorder 1 executes the recording processing procedure RT1 (FIG. 4) according to the voice recording program stored in advance in the ROM (not shown) of the control unit 20. However, the present invention is not limited to this. For example, the audio recording program may be stored in another storage medium such as the flash memory 21, or the audio recording program may be stored in a replaceable storage such as a Memory Stick (registered trademark). It is stored in a medium and the voice recording program is read and executed via a memory stick slot (not shown) or the like, or the voice recording is performed from a personal computer (not shown) or the like via the USB interface 27. You may make it acquire a program. In this case, the audio recording program may be restored by decompressing the compressed data or by executing an installation program.

  Further, in the above-described embodiment, the case where the IC recorder 1 as an audio recording device is configured by the AD / DA conversion circuit 24, the DSP 20B and the flash memory 21 as the recording means, and the CPU 20A as the control means has been described. The present invention is not limited to this, and an audio recording apparatus may be configured by a recording unit having various other circuit configurations and a control unit.

  The present invention can also be used in various audio recording apparatuses that encode audio and record it in a file.

It is a rough-line perspective view which shows the external appearance structure of an IC recorder. It is a block diagram which shows the circuit structure of an IC recorder. It is a basic diagram which shows the display content. It is a basic diagram which shows a recording process procedure. It is a basic diagram which shows the mode of the display of the audio | voice file in a personal computer.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... IC recorder, 6 ... Operation button group, 7 ... Right channel microphone, 8 ... Left channel microphone, 20 ... Control part, 20A ... CPU, 20B ... DSP, 21 ... Flash memory , 22, 23... Microphone amplifier, 24... AD / DA conversion circuit, 27... USB interface, S1, S2... Audio signal, D1, D2.

Claims (7)

Recording means for sequentially recording encoded data obtained by encoding audio in an audio file of a predetermined format;
When recording the encoded data to the audio file, a new audio file is created before the size of the audio file being recorded reaches the upper limit size of the audio file, and the recording destination of the encoded data is set to the new audio file. An audio recording apparatus comprising: control means for switching to an appropriate audio file. Display means for displaying the file name of the audio file,
The control means includes
The file name of the audio file displayed on the display means is not changed before and after switching the recording destination of the encoded data from the audio file to the new audio file, as if the encoded data is one audio file. The audio recording device according to claim 1, wherein the audio recording device is displayed so as to continue recording. A connection means for connecting to an external device capable of recognizing the audio file,
The control means includes
3. Recognizing that the external device is connected via the connection means, the external device recognizes the audio file and the new audio file as original independent audio files, respectively. The audio recording device according to 1. The recording means is
The audio recording apparatus according to claim 1, wherein the encoded data is generated by encoding the audio without being compressed. The recording means is
The audio recording apparatus according to claim 4, wherein the encoded data is recorded in an audio file in a WAV format. A recording step of sequentially recording encoded data obtained by encoding audio in an audio file of a predetermined format;
When recording the encoded data in the audio file, a new audio file is created before the size of the audio file being recorded reaches the upper limit size of the audio file, and the recording destination of the encoded data is changed to the new audio file. An audio recording method comprising: a control step for switching to an appropriate audio file. For voice recorder
A recording step of sequentially recording encoded data obtained by encoding audio in an audio file of a predetermined format;
When recording the encoded data in the audio file, a new audio file is created before the size of the audio file being recorded reaches the upper limit size of the audio file, and the recording destination of the encoded data is changed to the new audio file. And a control step for switching to an appropriate audio file.

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